2 research outputs found
Ultracold molecules: vehicles to scalable quantum information processing
We describe a novel scheme to implement scalable quantum information
processing using Li-Cs molecular state to entangle Li and Cs
ultracold atoms held in independent optical lattices. The Li atoms will
act as quantum bits to store information, and Cs atoms will serve as
messenger bits that aid in quantum gate operations and mediate entanglement
between distant qubit atoms. Each atomic species is held in a separate optical
lattice and the atoms can be overlapped by translating the lattices with
respect to each other. When the messenger and qubit atoms are overlapped,
targeted single spin operations and entangling operations can be performed by
coupling the atomic states to a molecular state with radio-frequency pulses. By
controlling the frequency and duration of the radio-frequency pulses,
entanglement can either be created or swapped between a qubit messenger pair.
We estimate operation fidelities for entangling two distant qubits and discuss
scalability of this scheme and constraints on the optical lattice lasers
Optical Lattices for Atom Based Quantum Microscopy
We describe new techniques in the construction of optical lattices to realize
a coherent atom-based microscope, comprised of two atomic species used as
target and probe atoms, each in an independently controlled optical lattice.
Precise and dynamic translation of the lattices allows atoms to be brought into
spatial overlap to induce atomic interactions. For this purpose, we have
fabricated two highly stable, hexagonal optical lattices, with widely separted
wavelengths but identical lattice constants using diffractive optics. The
relative translational stability of 12nm permits controlled interactions and
even entanglement operations with high fidelity. Translation of the lattices is
realized through a monolithic electro-optic modulator array, capable of moving
the lattice smoothly over one lattice site in 11 microseconds, or rapidly on
the order of 100 nanoseconds.Comment: 7 pages, 9 figure